Can't remember the details, but a lot of articles seemed to pop up a while ago, first about how Java was almost at the point of having some kind of consensus on getting closures, and then all of a sudden "oh, well, not this time"
If C++ proves that design by committee can work, then Java proves that it doesn't always work.
@jalf I seem to remember something like that as well. My impression was that Oracle wanted to just cut the debate and get some improvements out now. Roughly the same idea as removing Concepts from C++11 -- nobody wanted to, but realistically it just about had to be done.
@DavidRodríguezdribeas Great (or some sort of) minds think alike, I guess.
I'm probably biased, but I think the concepts thing had good reasons behind it though. They were pushing into unknown territory, and there were a lot of legitimate concerns about what effects it'd have. Whereas lambdas are... well, they could steal the spec from C#, and they'd more or less be home free
@jalf Personally, I kind of doubt it. The two languages haven't diverged enough for one to have a real advantage over the other, but just enough that they can't quite feed off each other that easily either.
@JerryCoffin yeah, but would there be any unique problems with lambdas in Java over lambsdas in .NET? I can't think of any unique obstacles that might require Java's implementation to be fundamentally different
the next language I would choose to learn would look like C, with classes, using objective-c dynamic binding with c++ syntax, using overrideable allocators so that the language syntax is agnostic to wether the implementation uses a heap, reference counted, garbage collected, or smart objects for memory management.
it would still be a prodecural language at its heart, as I belive that functional languages don't work because they dont map to how people naturally think
but it definately would have lambdas and co-routines.
anyway, I've kind of lost interest in imperative languages for educational purposes. Whether you call it C#, C++, Ruby or anything else, I don't really see much point in learning them, other than for practical reasons, if I end up needing it for a project
@ChrisBecke Doesn't work. GC removes deterministic destruction, which makes RAII essentially unworkable. That's exactly why the solutions trying to graft RAII onto Java and C# are so horrible and kludgy.
It could work in several ways. Either split the language so that some types are GC'ed and others have deterministic destruction (C# does that, although they could take it a lot further), or just separate destruction from memory release. Let the GC take care of reclaiming memory nondeterministically, but destroy the objects deterministically before then with RAII
@MartinhoFernandes What's horrible is that they don't centralize the RAII. Instead of the class designer being able to write it so it manages its own resources, they require the everybody who uses the class still has to deal with the resource management.
obj-c has an ugly syntax, and a high runtime overhead that is perhaps unavoidable, but it does have an elegant way of dealing with allocating and initializing objects and their descendants.
In C++, you can just create a variable, and when it goes out of scope, it will clean itself up. I don't have to think about, or know about, how to clean up after it
But in C#/Java, you have to specifically say "and now clean up this variable I've been using"
was the idea that the language had a runtime, that was written exactly the same way as user written functions were, for performing actions as basic as malloc().
@JerryCoffin Worse even: I have not really seen at the implementations of the classes that are manageable, but I assume that it will be similar to C# IDisposable, where the class requires a good amount of code to handle the resource (when it is dispose, and when it is not disposed and the finalizer is called, in case that the user forgot to dispose it), and then after making the class more complex it still requires user code to be aware and handle that in a using/try block
so, thinking that c++ was little more than c with classes (I was uneducated remember) I fell in love with the idea that languages should have as few keywords as possible, and that outtside of those, all language features should be user implementable.
On the lambda's issue, I don't think that they could have just grabbed C# lambdas and added that to Java as it is. The problem being that their different approaches to "closures" as of now differ greatly (with Java's being more cumbersome, a little more sane)
@jalf Maybe -- Modula III (for one example) certainly handled it a lot more cleanly than most since, but even there it got kludgy in places. Go seems (to me) to have a bit of the same problem. Even Smalltalk has some fairly nasty areas to deal with when you try to put it to serious use.
if c++ fitted my mental definition of "Elegant", then new, and delte, would have been methods added to classes using some generic syntax, that allowed different forms to be defined, and allowed them to not be defined at all.
@jalf They don't, but they do have a number of proposals, and seem to have decided on a rough idea of what they're going to do, and it's built on what's already there (anonymous, local classes).
I vaguely could, using templates, but then the result would be so clouded in template specific syntax that the result wouldn't be usable, in the same way that being able to MyClass* scndRef = retain frstRef;
I guess this drills down to the actual definition of variable, is the reference or the referred object the variable? Intuitively the object, in reality the reference, I guess
(given an appropriate x in scope...) Or we can get into a deeper discussion and say that C++ lambdas are closures sometimes but aren't some other times... (I don't really want to go that way...)
@FredOverflow Good, that interests me (sincerely, this is not ironic): What would be a definition of a captured variable, and a closure?
The captured variable must be guaranteed to live long for the closure. C++0x does not guarantee this. You can either copy (in which case you get a different variable), or you can capture by reference and hope that the lambda does not execute after the surrounding function has returned.
I'd argue that the main thing is that inside the closure, operating on the variable should have the same semantics as operating on it outside the closure. (Reseating the reference/pointer should be reflected outside the closure, for example)'
@FredOverflow Yes, the C# compiler cheats and creates a class for the captured variables. Sintactically they looks like variables, but they're really fields.
@FredOverflow It's not really just your personal taste -- it is pretty much part of the (usual) definition of "closure". At the same time, a true closure basically requires saving the entire current state of the program until some arbitrary later time, with essentially no ability to specify that time, even if you want to. As such, it really does pretty nearly require GC to work at all.
@MartinhoFernandes How is a field not a variable? And since when is implementing something in terms of older language features cheating? Is implementing virtual with vtables also cheating, because they are just arrays of function pointers? ;)
About concepts, my perception is that there were two conflicting vision of concepts. And the disagreement between holders of them frightened the one which had no opinion.
@MartinhoFernandes From the scope point of view, it still is a local variable, isn't it? :) It just does not live on the stack, but that should not matter.
@AProgrammer it's also my impression that one camp more or less went along, until they sprung the bombshell at the end that "what we're doing just isn't good enough. We need a rethink".
@FredOverflow Not in the same context. In C# (the language, not the implementation) there is no stack (well, outside unsafe code), but there are local variables.
@jalf In general. Concepts was one thing I knew I couldn't follow near enough. And then I had to drop following things I though I had enough time to follow.
@jalf I don't quite understand this, a reference is basically a pointer, and there is the lvalue (pointer itself) and the converted rvalue (value of the pointer), and we also have the pointed object (lvalue again), so which of the three is the variable?
According to @FredOverflow, it would be the pointer lvalue
(ouch, I hate using those terms, but I couldn't think of an explicit way of differentiating...)
@DavidRodríguezdribeas Yeah, but in C#, virtually everything is a reference, and references are copied by value, which would imply that if, inside a lambda, you reseated a captured reference, the change wouldn't be reflected outside the closure
my point is that it doesn't work like that, it works as if the closure saw a C++ reference (or an alias of the variable itself), not just a copy of a reference
The first sentence is a quote from elsewhere. See if this works: "Can you think of a legitimate reason why one would want to access an object after destruction? This is not a loaded question; it's just that I cannot think of a convincing example."
And, if I understand it correctly that is what actually happens (through some compiler trickery that involves stealing variables from the local context and moving them as attribute of the lambda) with C# lambdas, or not?
@DavidRodríguezdribeas When a lambda captures variables, the compiler creates a class with a field for each one and a method for the actual lambda. Then it rewrites the method and changes every usage of the variable to a field access.
> As others have pointed out, even though only objects of a relative few types need to be explicitly "destructed" (to close file handles, etc.), the need for deterministic destruction bubbles into any object of any type that contains one of those "relative few" objects. This is a much more serious problem than you appear to allow for.
@MartinhoFernandes Yes, yes... but the semantics are the same... however it is implemented the semantic are that changes inside and outside the lambda/function will be visible on the other end
So by @Fred's definition C# does have closures, or am I missing something?
@FredOverflow Yes -- Paul may not be particularly famous, but I generally thought he was an intelligent and (perhaps more importantly) sensible person.
> in my subjective opinion, we don't need it because it really doesn't give us much (if anything) over smart pointers with deterministic destruction in all cases. The areas that are interesting--that GC is typically used to enable--are things like backwards closures. Regular dynamic memory management is almost always trivial nowadays
or specifically the lifetime issue we talked about earlier, that the variable must still be alive when seen by the closure, even if it is long after it was in scope in the surrounding code
is my guess. That kiiinda fits with the "backwards" part
So if you held an object (call it variable, knowingly misleading, I know) through a shared_ptr, and you captured that shared ptr by value, then you would have a closure-of-sorts... on variable (not on the shared_ptr that holds it)
@FredOverflow Hm...I never thought nearly as highly of that Paul! (IMO, the Beatles are nearly tied with Led Zeppelin as "most overrated band of all time.")
@DavidRodríguezdribeas If your point was to show that a GC isn't necessary for closures, then I think you won ;)
and since these shared pointers would likely be an implementation detail invisible to user code, you wouldn't have to worry about circular references either
@jalf The problem is that some of the original variables (at least in C++) might be on the stack. Maybe GC isn't necessary, but you essentially have to enforce (like Java, et. do) that all variables are on the heap, where you can extend their lifetime as needed.
@JerryCoffin no, you just have to know in advance which variables are going to be captured, so the compiler can put them in a shared_ptr instead of on the stack
that's trivial, and just like what the C# compiler does
of course, performance would likely be better with a proper GC, but I can't see why the shared_ptr version wouldn't work correctly
It would also cause other problems, in that destructors would be called later than expected, as seen by the code "outside" the closure
@jalf You'd have to do a bit more than that, making it so the "normal" code dealing with the captured variables did so via a reference (e.g., roughly like Java and C# normally do). Ultimately, yes, if you change enough to make it almost like C# otherwise, you could end up with it working about like it does in C#...
I think that could actually be implemented outside of the core language, by means of libraries with type erasure, in the same way that std::function/boost::any work... so if you want to *actually* capture an integer variable you could write:
capturable<int> x;
std::function< void () > f = [=]() { /* operate on x */ }
:602113 Have you changed the array definition from:
int **A = new int *[rowsA];
into something like
int *A = new int[ rowsA*colsA ];
??
If you haven't, which looks like you haven't, then the problem is on what you are declaring and how you intend on using it
The variable definition above declares an array of *pointers* to ints, to properly allocate the memory you would have to do something like:
int **A = new int*[rowsA];
for ( int i = 0; i < rowsA; ++i )
A[i] = new int[colsA];
But that is generally not a great idea
But that is not generally a great idea. Search in SO proper for bidimensional arrays
@jalf For example, while the upload is progressing in the worker thread, the user may press a "Cancel" button in the main UI thread. So the boolean would be accessed from two different threads.
My usual implementation is to use a mutex. However, I tend to end up with lots of mutexes after a while..
Probably volatile will be sufficient in this situation.
you could do the same just with a few memory barriers and by ensuring that every access is atomic. But I'm not sure that's preferable in the general case
@jalf The only problem that I am aware of with volatile is reordering. However since I'm using method to encapsulate each kind of access I don't think it will be a problem.
@StackedCrooked kiiind of. There are plenty of C-style ones you could use if you really wanted to. I'm developing my own which basically works, but a few bits of it aren't as efficient as they should be ;)
also it comes with absolutely no warranties or support ;)
@jalf One complaint that I once read about transactional memory is that it requires the library to do a lot of book-keeping at runtime. So the speed advantage is lost.
yeah, as far as I'm concerned, it's not about gaining a speed advantage, but about providing safer and more intuitive semantics with a tolerable speed disadvantage
I think the discussions about it actually improving speed are mostly academic in nature
@DeadMG I think that is the only safe use of volatile for multithreaded. There is not much that can be reordered in a loop with respect to the loop condition. I.e. the compiler cannot reorder effects of the loop body to be executed after the condition is tested. And even if they could be reordered (i.e. the variable preloaded into a register) that would only imply that another iteration is executed. Am I missing something there?
it was my understanding that the main advantage of STM is that it just works, and if you're writing something with very high performance requirements, then you might want to go closer to the hardware
@StackedCrooked sec, just verifying that I've got the most recent version online. Like I said, it's still under development, so there's no documentation or anything :)
@StackedCrooked well, with the exception that with locks the responsibility is on the programmer to ensure that all code paths that access a variable are protected by locks
@StackedCrooked Yes, the use of a volatile variable there ensures that the compiler generates code to write to memory, the hardware then will invalidate the other processes caches and the change will be immediately visible by other threads
And atomic... well, setting a boolean variable is atomic, like reading an aligned int variable on intel platforms, which is different from incrementing which takes more operations read, increment, write.
@DavidRodríguezdribeas I find that I frequently need to lock single variables: "cancel flags", "quit flags", counters, etc.. And it results in many mutexes. I'm I the only one that has this?
@StackedCrooked I do it often, and note that there are actually very few cases where you can get along without doing it. For example, you cannot increment a counter without a lock (or using atomic operations)
I'm working on polishing off the last major feature of it (retry/orelse functions, as Haskell STM has), but after that, I'll put it "properly" online and write up some documentation and stuff
it should work in VC2010 and GCC 4.5 at least
atm it uses a few C++0x features, just out of convenience (a few autos and lambdas, nothing more), so it'd be fairly straightforward to get C++03 support as well
by the way, how does it work in clojure? I don't think I came across that when researching for my lib
@DeadMG isn't that correct? I don't think x86 has atomic add instructions
@jalf So STM means that two threads can start a transaction and access overlapping data. Only in case of a conflict one of the two transactions is cancelled. Right?
@DavidRodríguezdribeas in most cases. At the moment, it is possible to create a situation where it'll probably never terminate, which is one of the things I need to fix
@StackedCrooked at the moment, I don't. That's a side effect, which shouldn't take place inside a transaction
but if the delete is part of a larger data structure, then it can done since the transaction will operate on a private copy of the data structure, and when committing, write that back to the "outside" copy. So if, say, you deleted a node during the transaction, that change will be reflected properly
@StackedCrooked yup
@DavidRodríguezdribeas you have to try pretty hard to prevent it from terminating though. It won't happen just by accident
@StackedCrooked doesn't have to be local data, but they should avoid code that has side effects, yeah. Unless it is hidden away inside a RAII object or something, which will automatically do the right thing when it is copied into the transaction and back out at commit
I've got some ideas for allowing you allowing some side effects in transactions (by letting the user specify hooks to either commit or rewind the side effect, which are then called by the library), but that's not implemented yet
@StackedCrooked none, at the moment. What it does is just copying the shared object into a private buffer during the transaction, and then copying (or moving) it back when committing. So you can do what you like on that object, just remember that it will get copied once you're done, and it may be executed more than once (if the transaction rolls back and retries because of a conflict)
so, for example, if you deleted a node from a std::list, you'd be safe, because you're only deleting the node from the private copy, which no other thread will touch. And when committing, the original list will be overwritten by your modified one
but if you explicitly call delete on a variable, then you may be in trouble
@JamesMcNellis My first working day as a professional programmer was in 2005. The codebase I had to work with was started in 1999. It didn't use STL, instead they had written their own "Basic Framework Library". Reason was unreliable compatiblity and performance of STL across different platforms. Can you believe that?
